Identification of a procarboxypeptidase A-truncated protease E binary complex in human pancreatic juice

The characterization, in human pancreatic juice, of a binary complex associating procarboxypeptidase A with a 32 kDa inactive glycoprotein (G32) is reported in this paper. Free G32 was isolated after dissociation of the binary complex. N-terminal sequence analysis revealed a complete homology between this protein and human protease E (HPE 1), except for the two strongly hydrophobic N-terminal residues (Val-Val) which are missing in G32. This protein might be a truncated protease E highly analogous to the subunit III of the ruminant procarboxypeptidase A-S6 ternary complex. The analogy with bovine subunit III is further supported by interspecies reassociation experiments showing that bovine procarboxypeptidase A can specifically bind human G32.     

Morphology of the procarboxypeptidase A-S6 complex

Bovine pancreatic procarboxypeptidase A is secreted as a non-covalent association of three different proteins (pro CPA-S6). The free native subunits can be obtained by dissociation of the complex by dimethylmaleylation. Moreover, two specific binary complexes resulting from the high affinity of procarboxypeptidase A (subunit I) for its other two partners (subunits II and III) can also be obtained.In order to better understand the function of the association, an investigation of the morphology of the ternary complex by solution X-ray scattering has been carried out. The radii of gyration of all the molecular species have been obtained and the experimental results have been interpreted in terms of compact objects of simple shape. The various components correspond to globular particles as shown by the value of the ratio Rg/M^1/3. This is confirmed by the moderate anisotropy of the simple geometric shapes determined using an assumed value of 0.3 g H₂O/g protein for the hydration. The distances between the centres of gravity of pairs of species strongly suggest that the components are in the closest distance configuration or close to it. However, the binary complex I–III appears to be more open than the complex I–II. Finally, a model of the interaction between carboxpeptidase A and its activation peptide has been constructed by comparing the hypothetical geometric model of subunit I to the crystallographically determined structure of carboxypeptidase A.Abbreviations pro CPA procarboxypeptidase A - pro CPA-S6 (or T.C.) ternary complex with a sedimentation coefficient of 6S - CPA carboxypeptidase A     

Human procarboxypeptidase B: three-dimensional structure and implications for thrombin-activatable fibrinolysis inhibitor (TAFI)

Besides their classical role in alimentary protein degradation, zinc-dependant carboxypeptidases also participate in more selective regulatory processes like prohormone and neuropeptide processing or fibrinolysis inhibition in blood plasma. Human pancreatic procarboxypeptidase B (PCPB) is the prototype for those human exopeptidases that cleave off basic C-terminal residues and are secreted as inactive zymogens. One such protein is thrombin-activatable fibrinolysis inhibitor (TAFI), also known as plasma PCPB, which circulates in human plasma as a zymogen bound to plasminogen. The structure of human pancreatic PCPB displays a 95-residue pro-segment consisting of a globular region with an open-sandwich antiparallel-alpha antiparallel-beta topology and a C-terminal alpha-helix, which connects to the enzyme moiety. The latter is a 309-amino acid residue catalytic domain with alpha/beta hydrolase topology and a preformed active site, which is shielded by the globular domain of the pro-segment. The fold of the proenzyme is similar to previously reported procarboxypeptidase structures, also in that the most variable region is the connecting segment that links both globular moieties. However, the empty active site of human procarboxypeptidase B has two alternate conformations in one of the zinc-binding residues, which account for subtle differences in some of the key residues for substrate binding. The reported crystal structure, refined with data to 1.6A resolution, permits in the absence of an experimental structure, accurate homology modelling of TAFI, which may help to explain its properties.     

Two-dimensional isoelectric focusing/sodium dodecyl sulfate gel electrophoresis of protein mixtures containing active or potentially active proteases: Analysis of human exocrine pancreatic proteins

Analysis of human pancreatic juice in two dimensions using isoelectric focusing followed by sodium dodecyl sulfate gel electrophoresis indicated that human pancreatic trypsinogen (IEP_n = 6.4) rapidly autoactivated in the absence of the secretory trypsin inhibitor. The addition of 4 to 6 m urea to the protein sample and 8 m urea to the isoelectric focusing gel inhibited this autoactivation process and allowed the analysis of human exocrine pancreatic proteins. Thirteen discrete proteins were separated by the two-dimensional gel procedure including two forms each for trypsinogen, proelastase, and procarboxypeptidase A, and single forms each for amylase, lipase, procarboxypeptidase B, and chymotrypsinogen. The kinetics of inhibition of human trypsin by 8 m urea in the presence of ethylene glycol bis(β-aminoethyl ether)N,N′-tetraacetic acid indicated that samples containing active proteases could also be analyzed by this procedure.     

Generation of a subunit III-like protein by autolysis of human and porcine proproteinase e in a binary complex with procarboxypeptidase A

Tryptic treatment of human and porcine proproteinase E, procarboxypeptidase A binary complexes gave rise to active proteinase E after removal of an 11-residue N-terminal activation peptide. By contrast, upon treatment of either complex with active proteinase E, not only was the activation peptide released but also the hydrophobic dipeptide Val12-Val13 of the corresponding enzyme. No serine protease activity on specific synthetic peptide substrates could be detected. The structural homology of inactive proteinase E with subunit III of ruminant procarboxypeptidase A was strengthened by the existence of a functional homology since truncated proteinase E still possessed a weakly functional active site. Thus, subunit III-like proteins are generated by proteinase E-catalyzed limited proteolysis of proproteinase E.     

Purification and properties of five different forms of human procarboxypeptidases

Three different procarboxypeptidases A and two different procarboxypeptidases B have been isolated for the first time, in a pure and native state, from human pancreatic extracts. These proteins were purified in one or two quick steps by anion-exchange HPLC. All these forms have been biochemically characterized. Two of the procarboxypeptidases A, the A1 and A2 forms, are obtained in a monomeric state while the other, the A3 form, is obtained as a binary complex of a procarboxypeptidase A with a proproteinase E. This complex is stable in aqueous buffers at various ionic strengths and develops carboxypeptidase A and proteinase E activities in the presence of trypsin. The A1 and A2 forms show clear differences in electrophoretic mobility in SDS/polyacrylamide gels, isoelectric point, proteolytic activation process with trypsin and susceptibility to thermal denaturation. In contrast, these properties are similar in the A1 and A3 (binary complex) forms. On the other hand, with respect to the properties listed above, the B1 and B2 forms differ from each other mainly in isoelectric point. An overall comparison of the above properties reveals the unusual character of the A2 form, midway between the other A and B forms. N-terminal extended sequence analysis carried out on these proenzymes confirm that they constitute different isologous forms.     

Sequential homologies between procarboxypeptidases A and B from porcine pancreas

Automated Edman degradation of monomeric procarboxypeptidases A and B from porcine pancreas shows that their N-terminal regions (from residue 1 to 34-37) present a high degree of sequential homology to each other as well as to other related procarboxypeptidases. Conformational predictions based on these sequences confirm their structural homology and indicate the probable existence of two beta-turns, one beta-chain and a long alpha-helix in them. On the other hand, tryptic peptide maps on a reverse-phase column indicate great sequential similarities (if not identity) between monomeric procarboxypeptidase A and the procarboxypeptidase A subunit isolated from its binary complex with proproteinase E.     

Autolysis of proproteinase E in bovine procarboxypeptidase A ternary complex gives rise to subunit III

Extracts of bovine pancreatic tissue are shown by HPLC to contain two distinct ternary complexes of procarboxypeptidase A (subunit I), chymotrypsinogen C (subunit II) and either proproteinase E or subunit III. It is shown that proproteinase E in the complex generates subunit III by removal of 13 N-terminal residues when the former is allowed to autolyze in solution or when catalytic amounts of isolated active proteinase E are added to it. Autolysis of proproteinase E was accompanied by the loss of potential activity towards specific synthetic substrates and occurred at a higher rate in pancreatic juice than in pancreatic tissue extracts, even when both were processed in the presence of serine protease inhibitors. We conclude that subunit III (also called truncated protease E) is an autolytic product of proproteinase E and not an ab initio component of the native ternary complex.     

Intracellular proteolysis of pancreatic zymogens.

Activation of pancreatic digestive zymogens within the pancreatic acinar cell may be an early event in the development of pancreatitis. To detect such activation, an immunoblot assay has been developed that measures the relative amounts of inactive zymogens and their respective active enzyme forms. Using this assay, high doses of cholecystokinin or carbachol were found to stimulate the intracellular conversion of at least three zymogens (procarboxypeptidase A1, procarboxypeptidase B, and chymotrypsinogen 2) to their active forms. Thus, this conversion may be a generalized phenomenon of pancreatic zymogens. The conversion is detected within ten minutes of treatment and is not associated with changes in acinar cell morphology; it has been predicted that the lysosomal thiol protease, cathepsin B, may initiate this conversion. Small amounts of cathepsin B are found in the secretory pathway, and cathepsin B can activate trypsinogen in vitro; however, exposure of acini to a thiol protease inhibitor (E64) did not block this conversion. Conversion was inhibited by the serine protease inhibitor, benzamidine, and by raising the intracellular pH, using chloroquine or monensin. This limited proteolytic conversion appears to require a low pH compartment and a serine protease activity. After long periods of treatment (60 minutes), the amounts of the active enzyme forms began to decrease; this observation suggested that the active enzyme forms were being degraded. Treatment of acini with E64 reduced this late decrease in active enzyme forms, suggesting that thiol proteases, including lysosomal hydrolases, may be involved in the degradation of the active enzyme forms. These findings indicate that pathways for zymogen activation as well as degradation of active enzyme forms are present within the pancreatic acinar cell.     

The activation peptide of pancreatic procarboxypeptidase A is the keystone of the bovine procarboxypeptidase A-S6 ternary complex

In some ruminant species, pancreatic procarboxypeptidase A is the central element of a ternary complex involving two other components, a C-type chymotrypsinogen and an inactive protease E. Although the complex is devoted to protein digestion, the fate of this system upon activation of its constituent subunits has, as yet, not been clearly established. In this paper, the activation peptide of procarboxypeptidase A is shown to play a key role in the association of the three subunits and a model is proposed for the in vivo function of the complex.     

Comparison between the monomeric and binary-complex forms of procarboxypeptidase A from whole pig pancreas.

Two different forms of procarboxypeptidase A (I and II) were obtained from pig pancreas extracts. The Mr values, the pattern found on polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate, and the sedimentation coefficients indicate that form I is a binary complex formed by two different subunits, whereas form II is a monomer. The carboxypeptidase A-precursor subunit of form I and the form II monomer are very similar with respect to Mr value, amino acid composition and fragmentation by CNBr and iodosobenzoic acid. The activation process of both forms is unspecific with respect to the activating enzyme, the peptide released during activation is unusually long (Mr approx.sor subunit of form I and the form II monomer are very similar with respect to Mr value, amino acid composition and fragmentation by CNBr and iodosobenzoic acid. The activation process of both forms is unspecific with respect to the activating enzyme, the peptide released during activation is unusually long (Mr approx.sor subunit of form I and the form II monomer are very similar with respect to Mr value, amino acid composition and fragmentation by CNBr and iodosobenzoic acid. The activation process of both forms is unspecific with respect to the activating enzyme, the peptide released during activation is unusually long (Mr approx. 12500) and, in the case of the binary complex, the activation with trypsin follows a rather complex pattern, suggesting that the accompanying subunit of form I might play a modulating role in the activation process. Although the appearance of enzymic activity is rather slow, a protein with an Mr equivalent to that of active carboxypeptidase A is found very early in the activation process. Both zymogens are glycoproteins (so far no carbohydrate has been reported in any procarboxypeptidase A) and both contain two strongly bound Zn2+ ions/molecule. Other chemical and physical properties were also determined.     

Mapping the pro-region of carboxypeptidase B by protein engineering. Cloning, overexpression, and mutagenesis of the porcine proenzyme.

The proteolytic processing of pancreatic procarboxypeptidase B to a mature and functional enzyme is much faster than that of procarboxypeptidase A1. This different behavior has been proposed to depend on specific conformational features at the region that connects the globular domain of the pro-segment to the enzyme and at the contacting surfaces on both moieties. A cDNA coding for porcine procarboxypeptidase B was cloned, sequenced, and expressed at high yield (250 mg/liter) in the methylotrophic yeast Pichia pastoris. To test the previous hypothesis, different mutants of the pro-segment at the putative tryptic targets in its connecting region and at some of the residues contacting the active enzyme were obtained. Moreover, the complete connecting region was replaced by the homologous sequence in procarboxypeptidase A1. The detailed study of the tryptic processing of the mutants shows that limited proteolysis of procarboxypeptidase B is a very specific process, as Arg-95 is the only residue accessible to tryptic attack in the proenzyme. A fast destabilization of the connecting region after the first tryptic cut allows subsequent proteolytic processing and the expression of carboxypeptidase B activity. Although all pancreatic procarboxypeptidases have a preformed active site, only the A forms show intrinsic activity. Mutational substitution of Asp-41 in the globular activation domain, located at the interface with the enzyme moiety, as well as removal of the adjacent 310 helix allow the appearance of residual activity in the mutated procarboxypeptidase B, indicating that the interaction of both structural elements with the enzyme moiety prevents the binding of substrates and promotes enzyme inhibition. In addition, the poor heterologous expression of such mutants indicates that the mutated region is important for the folding of the whole proenzyme.     

Hormonal stimulation in the exocrine pancreas results in coordinate and anticoordinate regulation of protein synthesis

24-h intravenous caerulein infusion studies in the rat were combined with in vitro amino acid incorporation studies followed by high-resolution separation of proteins by two-dimensional isoelectric focusing and SDS gel electrophoresis to study the extent to which persistent changes in the biosynthesis of exocrine pancreatic proteins are regulated by cholecystokinin-like peptides. Beginning in the third hour of optimal hormone infusion at 0.25 microgram kg-1 h-1, changes were observed in the synthetic rates of 12 proteins, which progressed over the course of the 24-h study. Based on coordinate response patterns, exocrine proteins could be classified into four distinct groups. Group I (trypsinogen forms 1 and 2) showed progressive increases in synthetic rates reaching a combined 4.3-fold increase over control levels. Group II (amylase forms 1 and 2) showed progressive decreases in synthesis to levels 7.1- and 14.3-fold lower than control levels, respectively. Group III proteins (ribonuclease, chymotrypsinogen forms 1 and 2, procarboxypeptidase forms A and B, and proelastase 1) showed moderate increases in synthesis, 1.4-2.8-fold, and group IV proteins (trypsinogen 3, lipase, proelastase 2, and unidentified proteins 1-4) did not show changes in synthesis with hormone stimulation. Regulation of protein synthesis in response to caerulein infusion was specific for individual isoenzymic forms in the case of both trypsinogen and proelastase. The ratio of biosynthetic rates of trypsinogen forms 1 + 2 to amylase forms 1 + 2 increased from a control value of 0.56 to 24.4 after 24 h of hormonal stimulation (43.5-fold increase). Biosynthetic rates for an unidentified protein (P23) with an Mr = 23,000 and isoelectric point of 6.2 increased 14.2-fold, and the ratio of synthesis of P23 to amylase 2 increased 200-fold during caerulein infusion. During hormone stimulation the anticoordinate response in the synthesis of pancreatic glycosidases (decreased synthesis) and serine protease zymogens (increased synthesis) explain previous observations that showed little change in rates of total protein synthesis under similar conditions.     

Anchoring fibrils contain the carboxyl-terminal globular domain of type VII procollagen, but lack the amino-terminal globular domain

Type VII procollagen has been characterized as a product of epithelial cell lines. As secreted, it contains a large triple-helical domain terminated by a multi-globular-domained carboxyl terminus (NC-1), and a smaller amino-terminal globule (NC-2). The triple helix and the NC-1 domain have previously been identified in anchoring fibril-containing tissues by biochemical and immunochemical means, leading to the conclusion that type VII collagen is a major component of anchoring fibrils. In order to better characterize the tissue form of type VII collagen, we have produced a panel of monoclonal antibodies which recognize the NC-1 domain. Peptide mapping of these epitopes indicate that they are independent and span approximately 125,000 kDa of the total 150,000 kDa of each alpha chain contained in NC-1. All these antibodies elicit immunofluorescent staining of the basement membrane zone in tissues. Type VII collagen has been extracted from tissues. As previously reported, it is smaller than type VII procollagen, (Woodley, D. T., Burgeson, R. E., Lunstrum, G. P., Bruckner-Tuderman, L., and Briggaman, R. A., submitted for publication), and we now find that it predominantly occurs as a dimer. Following clostridial collagenase digestion, intact NC-1 has been recognized, indicating that the difference in apparent Mr between the tissue form of the molecule and type VII procollagen results from modification of the amino terminus. The size of the amino-terminal globule has been determined to be between approximately 96 and 102 kDa. Rotary shadowing analyses of extracted molecules indicate that dimeric molecules contain the NC-1 domain, but are missing intact NC-2. We propose that the tissue form monomer, Mr = 960,000, be referred to as "type VII collagen." These studies strongly suggest that anchoring fibrils contain dimeric molecules with intact NC-1 domains. The data also support the previous suggestion that the NC-2 domain is involved in the formation of disulfide bond-stabilized type VII collagen dimers, and is subsequently removed by physiological proteolytic processing.     

Existence of ternary complexes of procarboxypeptidase A in the pancreas of some ruminant species

The existence of procarboxypeptidase A, in the form of a non-covalent ternary complex containing the apparently inactive serine protease (subunit III), has so far been observed only in the ox pancreas. Evidence, obtained in the present study, shows that a ternary complex of procarboxypeptidase A, with a subunit III highly homologous with that of the bovine complex, is also present in two other ruminant species, sheep and goat. The biological significance of these complex forms of procarboxypeptidase A and the consistently high biosynthesis level of the apparently inactive subunit III in all three ruminant species is still unknown. Yet the synthesis of subunit III is not related to the animal diet since in the horse, which is a non-ruminant herbivorous animal, the procarboxypeptidase A is monomeric. Reassociation assays between either bovine subunits II or III and monomeric as well as binary forms of procarboxypeptidase A from various species show that, unlike subunit II, the recognition site for subunit III is highly conserved in all the procarboxypeptidases A and that bovine subunit II is different from porcine chymotrypsinogen C with regard to association.     

HLA-B27 in transgenic rats forms disulfide-linked heavy chain oligomers and multimers that bind to the chaperone BiP

To test the hypothesis that HLA-B27 predisposes to disease by forming disulfide-linked homodimers, we examined rats transgenic for HLA-B27, mutant Cys(67)Ser HLA-B27, or HLA-B7. In splenic Con A blasts from high transgene copy B27 lines that develop inflammatory disease, the anti-H chain mAb HC10 precipitated four bands of molecular mass 78-105 kDa and additional higher molecular mass material, seen by nonreducing SDS-PAGE. Upon reduction, all except one 78-kDa band resolved to 44 kDa, the size of the H chain monomer. The 78-kDa band was found to be BiP/Grp78, and the other high molecular mass material was identified as B27 H chain. Analysis of a disease-resistant low copy B27 line showed qualitatively similar high molecular mass bands that were less abundant relative to H chain monomer. Disease-prone rats with a Cys(67)Ser B27 mutant showed B27 H chain bands at 95 and 115 kDa and a BiP band at 78 kDa, whereas only scant high molecular mass bands were found in cells from control HLA-B7 rats. (125)I-surface labeled B27 oligomers were immunoprecipitated with HC10, but not with a mAb to folded B27-beta(2)-microglobulin-peptide complexes. Immunoprecipitation of BiP with anti-BiP Abs coprecipitated B27 H chain multimers. Folding and maturation of B27 were slow compared with B7. These data indicate that disulfide-linked intracellular H chain complexes are more prone to form and bind BiP in disease-prone wild-type B27 and B27-C67S rats than in disease-resistant HLA-B7 rats. The data support the hypothesis that accumulation of misfolded B27 participates in the pathogenesis of B27-associated disease.     

Amino-terminal maturation of the Bordetella pertussis filamentous haemagglutinin

The 220 kDa filamentous haemagglutinin (FHA) is a major adhesin of Bordetella pertussis and is produced from a large precursor designated FhaB. Although partly surface associated, it is also very efficiently secreted into the extracellular milieu. Its secretion depends on the outer membrane accessory protein FhaC. An 80 kDa N-terminal derivative of FHA, named Fha44, can also be very efficiently secreted in a FhaC-dependent manner, indicating that all necessary secre tion signals are localized in the N-terminal region of FhaB. A comparison of predicted and apparent sizes of FHA derivatives, in addition to immunoblot analyses of cell-associated and secreted FHA polypeptides, indicated that FhaB undergoes N-terminal maturation by the cleavage of an 8–9 kDa segment. However, phenotypic analyses of translational lacZ and phoA fusions showed that this segment does not function as a typical signal peptide. Co-expression of the Fha44-encoding gene with fhaC also did not allow for secretion of Fha44 in Escherichia coli. High levels of secretion could, however, be observed when the OmpA signal peptide was fused to the N-terminal end of Fha44. Regardless of the OmpA signal peptide-Fha44 fusion point, the E. coli-secreted Fha44 had the same M_r as that secreted by B. pertussis, indicating that the N-terminal proteolytic maturation does not require a B. perfussis-specific factor. Similar to FHA, the B. pertussis-secreted Fha44 contains an as yet uncharacterized modification at its N-terminus. This modification did not occur in E. coli and is therefore not required for secretion. The N-terminus of Fha44 secreted by E. coli was determined and found to correspond to the 72nd residue after the first in-frame methionine of FhaB. The N-terminal modification was also found not to be required for haemagglutination or interaction with sulphated glycoconjugates.     

The bovine pro-carboxypeptidase A-S6 ternary complex: a rare case of a secreted protein complex

Up to now, a non-covalent ternary complex in which the pro-carboxypeptidase A (subunit I) is associated to two functionally different proteins (subunits II and III) has only been found in the pancreas of ruminant species. In the other species studied so far, the pro-carboxypeptidase A is secreted either as a monomer or as a binary association with a functionally different protein. Subunit I is the immediate precursor of carboxypeptidase A. Subunit II is a chymotrypsinogen of the C-type, involved, like subunit I, in the degradation of proteins and peptides. Although closely related to the pancreatic serine endopeptidases, subunit III appears to be devoid of any specific enzymatic activity. Information about the spatial organization of the subunits in the ternary complex has been deduced from the sequential dissociation of the complex. In contrast to the mechanism of activation of subunits I and II, which is independent of their aggregation state, the catalytic properties of the resulting enzymes are sensitive to their aggregation state. Moreover, the structural basis of inactivity of subunit III as well as the physiological role of the ternary complex are also discussed in this review.     

Dynamics of Hepatitis C Virus (HCV) RNA-dependent RNA Polymerase NS5B in Complex with RNA

The hepatitis C virus (HCV) non-structural protein 5B (NS5B) is an RNA-dependent RNA polymerase that is essentially required for viral replication. Although previous studies revealed important properties of static NS5B-RNA complexes, the nature and relevance of dynamic interactions have yet to be elucidated. Here, we devised a single molecule Förster Resonance Energy Transfer (SM-FRET) assay to monitor temporal changes upon binding of NS5B to surface immobilized RNA templates. The data show enzyme association-dissociation events that occur within the time resolution of our setup as well as FRET-fluctuations in association with stable binary complexes that extend over prolonged periods of time. Fluctuations are shown to be dependent on the length of the RNA substrate, and enzyme concentration. Mutations in close proximity to the template entrance (K98E, K100E), and in the center of the RNA binding channel (R394E), reduce both the population of RNA-bound enzyme and the fluctuations associated to the binary complex. Similar observations are reported with an allosteric nonnucleoside NS5B inhibitor. Our assay enables for the first time the visualization of association-dissociation events of HCV-NS5B with RNA, and also the direct monitoring of the interaction between HCV NS5B, its RNA template, and finger loop inhibitors. We observe both a remarkably low dissociation rate for wild type HCV NS5B, and a highly dynamic enzyme-RNA binary complex. These results provide a plausible mechanism for formation of a productive binary NS5B-RNA complex, here NS5B slides along the RNA template facilitating positioning of its 3′ terminus at the enzyme active site.